Electronic lock and alarm system

ABSTRACT

In an electronic lock and alarm system, a sequence of digitally coded signals, specified by logically comparing input coded signals from a manually operated selector matrix and preset coded signals from a programmable code detector, is transmitted to a sequence recognizer computer for determining the validity of the coded sequence, and terminals such as door locks, ingnition switches, etc. are operated by the computer in one of several modes specified by a user discriminatingly operating the selector matrix. In a first mode, the terminals are opened for accessibility to the user. In a second mode, the terminals are closed for inaccessibility to the user and a main alarm in the immediate vicinity is energized. In an optional third mode, the terminals are opened for accessibility to the user and a silent alarm is energized at a remote location.

R27,0l3 12/1970 Hcdinetal.........................317/134X Primary Examiner-A. D. Pellinen Att0rneyMorse, Altman & Oates ABSTRACT In an electronic lock and alarm system, a sequence of digitally coded signals, specified by logically comparing input coded signals from a manually operated selector matrix and preset coded signals from a programmable code detector, is transmitted to a sequence recognizer computer for determining the validity of the coded sequence, and terminals such as door locks, ingnition switches, etc. are operated by the computer in one of several modes specified by a user discriminatingly operating the selector matrix. In a first mode, the terminals are opened for accessibility to the user. in a second mode, the terminals are closed for inaccessibility to the user and a main alarm in the immediate vicinity is energized. in an optional third mode, the terminals are opened for accessibility to the user and a silent alarm is energized at a remote location.

7 Claims, 3 Drawing Figures CONTROL SENSOR RESET VIOLATION SYSTEM Inventor: Steven G. Finn, 27 Nobscot Road, Newton, Mass. 02159 Filed: Jan. 5, 1970 United States Patent Finn [54] ELECTRONIC LOCK AND ALARM Patented April 25, 1972 3,659,154

2 Shoots-Sheet 1 CONTROL I 2 3 SEQUENCE 4 5 s A LOCK DETECTOR 7 g 9 A RECOGNIZER CONTROL LOCK |2 l6 I8 20 IO I I MAIN ALARM l SILENT I I ALARM CONTROL 5 L J v SOLENOID I54 E 20 a I74 6 V E I64 I68 R SOLENOID EUNGER H o H56 Duno 2 H7O INVENTOR STEVEN G. FINN BY %j% fla)f M) ATTORNEYS ELECTRONIC LOCK AND ALARM SYSTEM BACKGROUND AND SUMMARY The present invention relates to security devices and, more particularly, to lock and alarm systems that are actuated manually and operated electronically. Prior systems typically have utilized mechanical keys and locks or mechanical combination locks, in mechanical or electro-mechanical association with mechanical or electro-mechanical controls, In contrast, the present system utilizes manually operable selectors, digitally coded sequences and computer operated controls. Since a system of the present type involves the transfer of much more information than does a system of the prior type, it is capable of much greater functional versatility.

The primary object of the present invention is to provide an electronic lock and alarm system characterized by a manually operated selector for setting a binary coded matrix, a detector for responding with a digitally coded input sequence, a control for providing a digitally coded reference sequence, a sequence recognizer computer for providing output signals logically res onsive to a comparison of the input sequence and reference sequence, and locking devices which are actuated or deactuated in electro-magnetic response to the output of the sequence recognizer computer. In the illustrated example, the locking devices include the ignition switch and main safety lock of an armored financial truck.

Another object of the present invention is to provide an alarm system characterized by a main alarm and an optional silent alarm, which are responsive to the signals as at the output of the sequence recognizer computer, for alerting cognizant personnel in the immediate vicinity and at a distant location, respectively, that either an improper code has been set at the binary coded matrix or a security sensor has been activated.

The invention accordingly comprises the apparatus possessing the construction, combination of elements, and arrangements of parts that are exemplified in the following detailed disclosure, the scope of which will be indicated in the appended claims.

BRIEF DESCRIPTION OF DRAWING V DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT FIG. 1 illustrates an application of the present system to an armored truck. Generally, the system comprises a manually operated code input matrix for providing a selected sequence of binary coded signals, a programmable detector 12 for converting the selected sequence of binary coded signals to a sequence decimal coded signals, a control 14 for providing a sequence of digitally coded signals in response to output signals from detector 12, a sequence recognizer computer 16 for providing a plurality of output signals which are logically responsive to a comparison of the sequence of decimal coded signals and the sequence of digitally coded signals, the digitally coded signals controlling the sequence in which computer 16 operates, and a lock control 18 for rending a locking device 20 and an ignition switch (not shown) operative and inoperative in response to the signals as at the output of sequence recognizer computer 16. In the preferred embodiment of the present invention, output signals from sequence recognizer computer 16 are applied also to a main alarm 22, for example, a siren, for alerting cognizant personnel in the immediate vicinity and a silent alarm control 24, for example, a transmitter, for alerting cognizant personnel at a distant location. It is to be understood that the silent alarm system is an optional feature and is included in an alternative embodiment of the present invention. It will be readily appreciated that a plurality of security sensors (not shown) may be provided for activating main alarm control 22 for a variety of unauthorized acts, for example, opening the doors, breaking the windows, tampering with the ignition system, opening the hood compartment and etc. In the illustrated embodiment of the present invention, the combination locking system is installed in an armored truck 25. Switch matrix 10 is installed in the cab portion thereof; detector 12, control 14, sequence recognizer computer 16, lock control 18, locking device 20, main alarm 22, and silent alarm control 24 are located in the rear compartment of truck 25; and a silent alarm signaling device (not shown) is situated at a remote location. It is understood that, in alternate embodiments, the present invention is adaptable for other uses, for example, securing a vault.

As shown in FIG. 3, input matrix 10 includes a plurality of like switching devices, for example, push button switches 26a, 26b, and etc. for providing a sequence of binary coded signals. The push button switches are connected to correlative logic circuits, for example, set-reset flip-flops denoted by reference characters 28a, 28b, and etc. Push button switch 260 is connected to set-reset flip-flop 28a, push button switch 26b is connected to set-reset flip-flop 28b and so on. The signal as at the output of set-reset flip-flop 28a is designated as l, the s ignal as at the output of set-reset flip-flop 28b is designated as 2, and so on. The signals as at the output of the set-reset flipflops represent the positive switching state of their correlative push button switches, i.e. signals which appear at the output of the push button switches as a result of switch bounce are not present at the output of the set-reset flip-flop. If bounce signals are not present at the output of the switches, the setreset flip-flops may be eliminated. Selected output terminals of the set-reset flip-flops are electrically connected to a plurality of NAND-gates 30, 32, 34, and 36 in such a manner that the outputs of flip-flops 28a, 28e, 28f, and 28g are applied to the input of NAND-gate 30; the outputs of flip-flops 28b, 28c, 28h, and 28j are applied to the input of NAND-gate 32; the outputs of flip-flops 28c, 28f, 28h, and 281' are applied to NAND-gate 34; and the outputs of 28d, 28g, 281', and 28j are applied to NAND-gate 36. For convenience, the signal as at the output of NAND-gates 30, 32, 34 and 36 will be referred to as B1, B2, B3, and B4, respectively. Input switch matrix 10 includes also a RESET switch 23 for resetting the system from alarm-off and locks open to alarm-on and locks closed and for cancelling partial codes entered into matrix 10, and ON light 27 for indicating the locking and alarm system operative and a STANDBY light 29 for indicating locking system and alarm system inoperative.

Detector 12, which produces a sequence of digitally coded signals responsive to the sequence of binary coded signals as at the output of matrix 10 and a preset sequence of decimally coded signals, includes a plurality of NAND-gates 38, 40, 42, and 44 for receiving the signals as'at the output of NA ND gates 30, 32, 34, and 36, respectively. Signals Bl, B2, B3, B4 as at the output of NAND-gates 38, 40, 42, and 44, respectively, are applied to their respective inputs of NAND-gate 46. The output of NAND-gatE 46 is logically connected to N'AND-gates 48, 50,54, and 56. The signals as at the output of NAND-gates 30, 32, 34, 36, 38, 40, 42, and 44 are applied to selective input terminals of NAND-gates 58, 60, 62, 64, 66, 68, 70, 72, 74, and 76 in such a manner that the sigr i al s at th e output of each of the NAND-gates is T, 2, 3, 4, 5, 6, 7, 8, 9, and 0, respectively. The output terminal of each NAND-gate 58, 60, 62, 64, 66, 68, 70, 72, 74, and 76 is connected to each of a plurality of switching devices 78, 80, 82, and 84, for example, rotary switghes eacl o f t he r9 tary s vitches receiving one coded signals 1, 2, 3, 4, 5, 6, 7, 8, 9, and 0. The output terminal of rotary switches 78, 80, 82, and 84 are connected to NAND-gates 86, 88, 90, and 92 respectively. For convenience, the signal as at the output of NAND-gates 86, 88, 90, and 92 will be designated as A A A and A respectively.

Control 14, which produces a sequence of digitally coded signals responsive to an output of NAND-gate 56, includes a NAND-gate 94 which is electrically connected to the output of NAND-gate 56, a JK flipflop 96 the first input of which is connected to the output of NAND-gate 94, a clock 98, and a NAND-gate 97 which are connected the second and third inputs of J K flip-flop 96, respectively. The output of flip-flop 96 is connected to the first inputs of J K flip-flops 100 and 102 via NAND-gates 104 and 106, respectively. The output terminal of J K flip-flop 100 is connected to second input terminal of J K flip-flop 102. For convenience, the outputs oiJK flip-flops 100 and 102 will be designated 0,, Q and Q Q respectively. Q,- as at the output of a NAND-gate 103 is applied to the input of NAND-gate 97 whereby clock 98 is de-energized. The outputs of JK flip-flop 100, JK flip-flop 102, and NAND- gate 106 are connected selectively to AND-gate 105, AND- gate 107, and NAND-gate 108. The first input of each AND- gate 105, AND-gate 107, and iiANp gate 1 08 is connected to NAND-gate 106 and O1, 62; Q,, Q; and Q 0 respectively. For convenience, the signal as at the output of NAND-gate 108 will be designated as logic done pulse and the signal as at the output of AND-gate 107 will be designated as C. The output of AND-gate 105 is connected to the first inputs of J K flip-flops 110 and 112. The output terminal of J K flip-flop 110 is connected to the second input of JK flip-flop 112. Th e outputs of JK flip-flops 110 and 112 are designated Q3, Q and O4, 6,, respectively. The output terminals of JK flip-flops 110 and 112 are connected selectively t2 AND-gates 114, 116, and 118 in such a manner that Q3, Q4 are applied to AND- gate 114, Q3, Q4 are applied to AND-gate 116, and Q3, Q4 are applied to AND-gate 118. The signals as at the output of AND-gates 114, 116, and 118 are designated S1, S2, and S3, respectively.

Sequence recognizer computer 16, which provides output control signals responsive to the sequence of digitally coded signals as at the outputs of detector 12 and control 14, includes four NAND-gates 120, 122, 124, and 126. The inputs of NAND-gates 120, 122, 124, and 126 are connected selectively to the outputs of NAND-gates 86, 88, 90, 92 and gates 107, 114, 116, and 118 in such a manner that each signal S C, and A is applied to one of the inputs of NAND-gate 120; each signal 8,, C, and A is applied to one of the inputs of NAND-gate 122; each signal S C, and A is applied to one of the inputs of NAND-gate 124; and each signal S C, and A is applied to one of inputs of NAND-gate 126. Each of the output terminals of NAND-gates 120, 122, 124, and 126 are connected to each of the input terminals of a combination of NAND-gates 128, 130, 132, and 134, respectively. The signals as at the outputs of NAND-gates 128 and 130 are applied to their correlative inputs of NAND-gates 136, 138, and 140, respectively. The outputs of NAND-gates 132 and 134 are connected to their respective inputs as at OR-gate 142. In addition, the output of NAND-gate 132 is connected to an input of NAND-gate 138 and the output terminal of NAND-gate 140 is connected to each of the inputs of NAND-gate 144 and 146. The output of NAND-gate 146 is connected to the first input of NAND-gate 148. The second input of NAND-gates 144 and 148 are joined at a junction 150. The output of NAND-gate 148 is connected to an input of a set-reset flipflop 152.

As shown in FIG. 2, locking device 20, which controls accessibility and inaccessibility to the rear compartment of truck 25, includes solenoids 154 and 156 which are electrically connected to locking control 18. Each of the solenoids 154 and 156 are provided with plungers 158 and 160 respectively. Plungers 158 and 160 are held in the extended position by springs 162 and 164, respectively, when their correlative solenoids are de-energized. Firmly affixed to plunger 158 is a locking pin 166 which is slidably seated in a guide 168 and a catch 170. Firmly affixed to plunger 160 is a bolt 172 which is removably seated in a catch 174. Bolt 172 isformed with channels 176 and 178 which are slightly larger than locking pin 166 so that bolt 172 is held immovable in the extended and retracted positions by locking pin 166. When an open lock signal, for example voltage V is applied to lock control 18, solenoid 154 is energized and plunger 158 is retracted into solenoid 154, whereby locking pin 166 is withdrawn from channel 176. In addition, the open lock signal energizers solenoid 156 and plunger 160 is retracted into solenoid 156, in consequence bolt 172 is withdrawn from catch 174 and lock 20 is rendered inoperative. It is noted, lock 20 is a fail safe device in that both solenoids 154 and 156 must be energized in order for bolt 172 to be withdrawn from catch 174.

In operation of the lock and alarm system, three of the push buttons switches 26 of switch matrix 10 are energized in the proper sequence as specified by position of rotary switches 78, 80, 82, and-84, whereby an open lock signal is applied to solenoids 154 and 156 and locking device 20 is rendered inoperative. It will be appreciated that, in an alternate embodiment, the number of switches comprising the proper combination is other than three, for example, four. In addition to the proper opening sequence, there are two other modes of operation, namely a main alarm mode and a silent alarm mode. When an improper code sequence is received from switches 26 or if locking device 20 is tampered with, main alarm 22 is activated, whereby personnel in the immediate vicinity are alerted and locking device 20 is rendered operative. If the armored truck personnel are under duress and forced to open the locking system, a special sequence code is selected and the silent alarm mode is energized. 1n the silent alarm mode locking device 20 is rendered inoperative (open) and silent alarm 24 is activated, in consequence cognizant personnel at a remote location are alerted.

As previously stated, locking device 20 is rendered inoperative when the proper sequence of binary coded signals, as specified by the position of rotary switches 78,80, 82, and 84, are selected at input switch matrix 10. When push button switches 26 are energized sequentially, correlative flip-flop 28 is locked in a set state and the energized push button switches 26 are disabled. The signal as at the output of the correlative flip-flops 28 are applied to the respective NAND-gates 30, 32, 34, and 36, in consequence signals B1, B2, B3, and B4 are applied to detector 12. Signals B1, B2, B3, and B4 are applied to their correlat ive NAND gates in detector 12 whereby coded signals B1, B1, B2, B2, B B B and B are presented at terminals 1 82, l84, 186, 188, 190, 192, 194, and 196, respectively. The B1, B B and B signals are applied to their respective inputs of NAND-gate 46, in consequence a ZERO logic initiate signal, for example, is presented at the output of NAND- gate 56. When the ZERO logic initiate pulse is applied to .1K flip-flop 96 via NAND-gates 94 and 97, flip-flop 96 changes state and clock 98 is activated. The change of state of JK flipflop 96, designated 0, is applied to J K flip-flops and 102 via NAND-gates 104 and 106, whereby Q 0,, and Q Q signals are presented at the outputs of J K flip-flops 100 and 102, respectively. Signals Q}, Q and the signals as at the output of NAND-gate 106 are applied to the input of N AND-gate 108, whereby a logic done pulse is presented at the output thereof. The logic done pulse, a ZERO, is applied to a terminal 198 at the input of NAND-gate 54, in consequence the signal as at the output of NAND-gate 54 is ONE, the signal as at the output of NAND-gate 52 is ZERO, and the logic initiate pulse as at output of NAND-gate 56 is ONE. A ONE as at the output of NAND-gate 56 releases the first energized push button switch 26, in consequence the coded signal representing the second energized push button switch 26 is applied to the input of NAND-gates 38, 40, 42, and 44 of detector 12. [Zuring die time that the logic initiate pulse is ZERO, the B1, B B B B B B and 8., binary coded signals as at the output of NAND-gates 38, 40, 42, and 44 are applied selectively to the inputs of NAND-gates 58, 60, 62, 64, 66, 68, 70, 72, 74, and 76 wherein the binary coded signals are conv rt ed to decimal goded signals. All the decimal coded number 1, 2,3 4,5,6, 7, 8, 9, 0 as at the output of NAND-gates 58, 60, 62, 64, 66, 68, 70, 72, 74, and 76, respectively, are applied to each of the rotary switches 78, 80, 82, and 84. Signals A A A and A specified by the preset position of their corresponding rotary switch, are presented at the output of NAND-gates 86, 88, 90, and 92, respectively. During the time the logic initiate pulse is ZERO, the'signal as at the output of NAND-gate 106 is applied also to AND-gates 105 and 107, whereby JK flip-flops 110 and 112 change state in response to the signal as at their inputs. JK flip-flops 110 and 112 provide a sequence of signals 8,, S and each of which is specified by the sequence in which push button switches 26 are energized. That is, the first logic initiate pulse, which is specified by the first energized push'button switch 26, causes a J K flip-flop 110 to be in a state ONE (designated at this time .114 flip-flop 112 is in state ZERO (designated 6 the second logic initiate pulse, which is specified by the second energized push button switch 26, c auses JK flip-flop 110 to be in a state ZERO (designated as Q and JK flip-flop 112 to be in a state ONE (designated as Q and the third initiate pulse, which is specified by the third energized push button switch 26, causes a JK flip-flop 110 to be in a state ONE and JK flip-flop 112 remains in state ONE. The Q Q, Q,,, and Q signals as at the output terminals of their correlative JK flip-flops 110 and 112 are selectively applied to AND-gates 114, 116, and 118 in such a manner that their respective output specify the sequence in which push button switches 26 are energized.

Signals 5,, S S A,, A A A and C are applied selectively to the inputs of NAND-gates 120, 122, 124, and 126 of sequence recognizer computer 16. When the signals S, and A, as at the input of NAND-gate 120 are both ONE, application of signal C causes NAND-gate 128 to latch. Similarly, whefi the correlative A and S signals as at the input of NAND-gates 122, 124, and 126 are ONES, application of signals C thereat causes NAND-gate 130, 132, and 134, respectively to latch. The signals as at the output of NAND-gates 128, 130, and 132 or 134 are applied to NAND-gate 140. When the complete three digit code has been entered, the logic done pulse is applied to junction 150 via NAND-gates 199 and 201, thereby setting the inputs of NAND-gates 144 and 148. In addition, the signal as at the output of NAND-gate 201 is applied to the input of NAND-gates 136 and 138. If push button switches 26 are energized in the proper sequence, the signal is at the output of NAND-gate 140 is applied as an open signal to the input of lock control 18 via NAND-gates 146, 148 and 152. If the push button switches are energized in an improper sequence, the output of NAND-gate 140 is applied as a close signal to the input of lock control 18 and as an alarm signal to a main alarm control 200, in consequence an alarm signal is applied to main alarm 22 via a NAND-gate 202, an AND-gate 204, and NAND-gates 206 and 208. In addition, if locking device 20 is tampered with a sensor violation signal is applied to NAND-gate 202 and main alarm 22 is activated. When the push button switches 26 are energized in the silent alarm mode sequence, the signal as at the output of NAND-gate 134 is applied to the first input of NAND-gate 136 and the signals as at the output of NAND-gates 128, 130, and 132 are applied to their respective inputs of NAND-gates 136 and 138. The signals as at the output of 136 and 138 are applied to a NAND-gate 210 in silent alarm control 24, in consequence a silent alarm 212 activates an alarm signaling device (not shown) at a distant location. In addition to activating the silent alarm signaling device, the silent alarm mode renders locking device 20 inoperative, i.e. open.

Since certain changes may be made in the foregoing disclosure without departing from the scope of the invention herein involved, it is intended that all matter contained in the above description and shown in the accompanying drawings be construed in an illustrative and not in a limiting sense.

lclaim:

1. A locking system comprising:

a. input matrix means including a plurality of first switch means for generating coded signals;

b. detector means including a plurality of first gate means and second switch means, said first gate means operatively connected to said first switch means, said first gate means operatively connected to said second switch means, said detector means generating first signals responsive to said signals generated by said input matrix means and governed by said second switch means;

0. control means, including a plurality of flip-flop means for generating second signals, operatively connected to said detector means, said control means responsive to said detector means;

d. sequence recognizer computer means, including a plurality of second gate means, operatively connected to said second switch means, and flip-flop means for generating third signals, the output signal of said sequence recognizer computer means responsive to said first and second signals of said detector means and control means, respectively; and

. locking means operatively connected to said sequence recognizer computer means, said locking means being rendered operative and inoperative in response to selected third signals as at the output of said sequence recognizer computer means.

2. The locking system of claim 1 wherein said system includes main alarm means operatively connected to said sequence recognizer computer means and responsive to selected signals as at the output of said sequence recognizer computer means, said main alarm means alerting cognizant personnel in the immediate vicinity of said locking system.

3. The locking system of claim 1 wherein said system includes silent alarm means operatively connected to said sequence recognizer computer means and responsive to selected third signals as at the output of said sequence recognizer computer means, said silent alarm means alerting co gnizant personnel at a distant location from said locking system.

4. The locking system of claim 1 wherein said first switch means is a plurality of push button switches, each said push 5 button switch providing a specified binary code.

5. The locking system of claim 1 wherein said second switch means is a plurality of rotary switch means for specifying a sequence of signals which renders said locking means operative and inoperative.

6. A locking and alarm system comprising:

a. input switch means for generating coded signals;

b. detector means including first gate means and switch means, for generating first signals, said first gate means operatively connected to said input switch means, said switch means operatively connected to said first gate means, said detector means first signals responsive to said coded signals of said input switch means and said switch means;

. control means including flip-flop means for generating control signals, said flip-flop means operatively connected to said detector means, said control means responsive to said detector means;

d. sequence recognizer computer means operatively connected to said switch means and flip-flop means for generating second signals, said second signals responsive to said first and control signals of said detector means and control means, respectively;

. locking means operatively connected to said sequence recognizer computer means, said locking means being rendered operative and inoperative in response to selected second signals as at the output of said sequence recognizer computer means; and

. alarm means operatively connected to said sequence recognizer computer means and responsive to selected second signals as at the output of said sequence recognizer computer means.

7. The locking and alarm system of claim 6 wherein said detector means includes a plurality of rotary switch means operatively connected to said input switch means for specifying a sequence of coded signals which renders said locking means operative and inoperative and activates and deactivates said alarm means. 

1. A locking system comprising: a. input matrix means including a plurality of first switch means for generating coded signals; b. detector means including a plurality of first gate means and second switch means, said first gate means operatively connected to said first switch means, said first gate means operatively connected to said second switch means, said detector means generating first signals responsive to said signals generated by said input matrix means and governed by said second switch means; c. control means, including a plurality of flip-flop means for generating second signals, operatively connected to said detector means, said cOntrol means responsive to said detector means; d. sequence recognizer computer means, including a plurality of second gate means, operatively connected to said second switch means, and flip-flop means for generating third signals, the output signal of said sequence recognizer computer means responsive to said first and second signals of said detector means and control means, respectively; and e. locking means operatively connected to said sequence recognizer computer means, said locking means being rendered operative and inoperative in response to selected third signals as at the output of said sequence recognizer computer means.
 2. The locking system of claim 1 wherein said system includes main alarm means operatively connected to said sequence recognizer computer means and responsive to selected signals as at the output of said sequence recognizer computer means, said main alarm means alerting cognizant personnel in the immediate vicinity of said locking system.
 3. The locking system of claim 1 wherein said system includes silent alarm means operatively connected to said sequence recognizer computer means and responsive to selected third signals as at the output of said sequence recognizer computer means, said silent alarm means alerting cognizant personnel at a distant location from said locking system.
 4. The locking system of claim 1 wherein said first switch means is a plurality of push button switches, each said push button switch providing a specified binary code.
 5. The locking system of claim 1 wherein said second switch means is a plurality of rotary switch means for specifying a sequence of signals which renders said locking means operative and inoperative.
 6. A locking and alarm system comprising: a. input switch means for generating coded signals; b. detector means including first gate means and switch means, for generating first signals, said first gate means operatively connected to said input switch means, said switch means operatively connected to said first gate means, said detector means first signals responsive to said coded signals of said input switch means and said switch means; c. control means including flip-flop means for generating control signals, said flip-flop means operatively connected to said detector means, said control means responsive to said detector means; d. sequence recognizer computer means operatively connected to said switch means and flip-flop means for generating second signals, said second signals responsive to said first and control signals of said detector means and control means, respectively; e. locking means operatively connected to said sequence recognizer computer means, said locking means being rendered operative and inoperative in response to selected second signals as at the output of said sequence recognizer computer means; and f. alarm means operatively connected to said sequence recognizer computer means and responsive to selected second signals as at the output of said sequence recognizer computer means.
 7. The locking and alarm system of claim 6 wherein said detector means includes a plurality of rotary switch means operatively connected to said input switch means for specifying a sequence of coded signals which renders said locking means operative and inoperative and activates and deactivates said alarm means. 